Project description:Targeting aberrant epigenetic programs that drive tumorigenesis is a promising approach to cancer therapy. DNA-encoded small-molecule library (DEL) screening is a core platform technology increasingly used to identify drugs that bind to protein targets. Here, we use DEL screening against bromodomain and extra-terminal motif (BET) proteins to identify inhibitors with new chemotypes, and successfully identified BBC1115 as a selective BET inhibitor. While BBC1115 does not structurally resemble OTX-015, a clinically active pan-BET inhibitor, our intensive computational modeling and biological characterization revealed that BBC1115 binds to BET protein BRD4 and suppresses aberrant cell fate programs. Phenotypically, BBC1115-mediated BET inhibition impaired proliferation in acute myeloid leukemia, pancreatic, and colorectal cancer cells in vitro. Moreover, intravenous administration of BBC1115 inhibited subcutaneous pancreatic and colorectal cancer xenograft growth with minimal toxicity and favorable pharmacokinetic properties in vivo. Since epigenetic regulations are ubiquitously employed across normal and malignant cells, it will be critical to evaluate whether BBC1115 interferes with normal cellular functions. Nonetheless, our study implicates that integrating DEL-based small-molecule compound screening and multi-step biological validation represents a reliable strategy to discover new chemotypes with selectivity, efficacy, and safety profiles for targeting proteins involved in epigenetic regulation in human malignancies.

Project description:Identification of the mechanisms through which BET inhibitor (OTX-015) stimulates natural killer (NK) activation. RNA-seq was performed comparing vehicle- (DMSO) to OTX-015-treated NK-92 cell line.

Project description:Bromodomain and extra terminal domain (BET) inhibition reduces occupancy of BET-family proteins at promoter and enhancer sites finally leading to genome wide changes in gene transcription. We used ChIPSeq profiling to investigate genome wide changes in promoter and enhancer occupancy induced by BET inhibitors BAY 1238097 and OTX-015, respectively.

Project description:Neural stem cells (NSCs) and progenitor cells (NPCs) are increasingly appreciated to hold great promise for regenerative medicine to treat CNS injuries and neurodegenerative diseases. However, evidence for effective stimulation of neuronal production from endogenous or transplanted NPCs for cell replacement with small molecules remains limited. To identify novel chemical entities/targets for neurogenesis, we had established a NPC phenotypic screen assay and validated it using known small-molecule neurogenesis inducers. Through screening small molecule libraries with annotated targets, we identified BET bromodomain inhibition as a novel mechanism for enhancing neurogenesis. BET bromodomain proteins, Brd2, Brd3, and Brd4 were found to be downregulated in NPCs upon differentiation, while their levels remain unaltered in proliferating NPCs. Consistent with the pharmacological study using bromodomain selective inhibitor (+)-JQ-1, knockdown of each BET protein resulted in an increase in the number of neurons with simultaneous reduction in both astrocytes and oligodendrocytes. Gene expression profiling analysis demonstrated that BET bromodomain inhibition induced a broad but specific transcription program enhancing directed differentiation of NPCs into neurons while suppressing cell cycle progression and gliogenesis. Together, these results highlight a crucial role of BET proteins as promising epigenetic regulators in NPC development and suggest a therapeutic potential of BET inhibitors in treating CNS injury and neurodegenerative diseases. NPCs were treated with (+)-JQ-1 or inactive enantiomer (-)-JQ-1 at 0.2 μM or 0.5 μM for 12 and 24 hrs in differentiation medium. The experiments were carried out in 3 independent preparations of NPCs (triplicates)

Project description:We investigated that differentially expressed genes (DEG) targeted by BET inhibitors, JQ1 and OTX-015 in HCC cells using RNA sequencing. These DEGs are involved in HCC cells migration, of which SMARCA4 inhibition is effective in suppressing HCC cell migration.

Project description:Transcriptional changes were analyzed in two colorectal cancer, two pancreatic cancer, and one small cell lung cancer cell line following treatment with the BET inhibitor GSK525762 and/or the MEK inhibitor trametinib using Affymetrix Human Genome U133 Plus 2.0 Arrays.

Project description:Neural stem cells (NSCs) and progenitor cells (NPCs) are increasingly appreciated to hold great promise for regenerative medicine to treat CNS injuries and neurodegenerative diseases. However, evidence for effective stimulation of neuronal production from endogenous or transplanted NPCs for cell replacement with small molecules remains limited. To identify novel chemical entities/targets for neurogenesis, we had established a NPC phenotypic screen assay and validated it using known small-molecule neurogenesis inducers. Through screening small molecule libraries with annotated targets, we identified BET bromodomain inhibition as a novel mechanism for enhancing neurogenesis. BET bromodomain proteins, Brd2, Brd3, and Brd4 were found to be downregulated in NPCs upon differentiation, while their levels remain unaltered in proliferating NPCs. Consistent with the pharmacological study using bromodomain selective inhibitor (+)-JQ-1, knockdown of each BET protein resulted in an increase in the number of neurons with simultaneous reduction in both astrocytes and oligodendrocytes. Gene expression profiling analysis demonstrated that BET bromodomain inhibition induced a broad but specific transcription program enhancing directed differentiation of NPCs into neurons while suppressing cell cycle progression and gliogenesis. Together, these results highlight a crucial role of BET proteins as promising epigenetic regulators in NPC development and suggest a therapeutic potential of BET inhibitors in treating CNS injury and neurodegenerative diseases.

Project description:Pancreatic ductal adenocarcinoma (PDAC) is extraordinarily chemoresistant and the abundant stromal content of these tumors contributes to the ineffective treatment of this disease. While the genetic alterations of PDAC have been well characterized, the epigenetic pathways regulating PDAC remain, for the most part, elusive. Employing an in vivo shRNA screen targeting epigenetic regulators, we identified members of the BET family of chromatin adaptors as key regulators of PDAC cell growth and maintenance of the tumor stroma. BET family members contribute to PDAC cell growth by modulating the activity of two key transcriptional programs, MYC and GLI. Within the cancer cells, BET inhibition also results in down-regulation of a key mediator of the tumor microenvironment, SHH, corresponding to a decrease in the stromal content of tumors. Taken together, these results suggest that therapeutic inhibition of BET proteins offers a novel mechanism to target both the neoplastic and stromal components of PDAC. Total RNA was isolated from 4 untreated PDAC cell lines or those exposedto the BET bromodomain inhibibitor CPI203 (1.6 uM) or control DMSO for 5 and 10 hours

Project description:Transcriptional profiling of the human pancreatic cancer cell line SUIT-2 that were infected with a GFP encoding adenoviral construct based on Human Adenovirus 5 and treated with epigenetic modifiers I-bet-762, NEO27034 or OTX015 compared to uninfected and untreated cells. Cells were infected with 1pfu AdWTGFP in serum free media for 2 hours. Cells were then washed and cultured in media containing 2% FBS for 10 hours. Cells were then treated with I-bet-762, NEO27034, OTX015 or DMSO in media containing 2% FBS for 12 hours. Infected GFP+ cells were isolated by FACS. GFP+ and control cells were processed for RNA-seq.

Project description:Bromodomain and extra-terminal domain (BET) proteins are therapeutic targets in several cancers including the most common malignant adult brain tumor glioblastoma (GBM). Multiple small molecule inhibitors of BET proteins have been utilized in preclinical and clinical studies. Unfortunately, BET inhibitors have not shown efficacy in clinical trials enrolling GBM patients. One possible reason for this may stem from resistance mechanisms that arise after prolonged treatment within a clinical setting. However, the mechanisms and timeframe of resistance to BET inhibitors in GBM is not known. To identify the temporal order of resistance mechanisms in GBM we performed quantitative proteomics using multiplex-inhibitor bead mass spectrometry and demonstrated that resistance to BET inhibitors in GBM treatment occurs rapidly within hours and involves the fibroblast growth factor receptor 1 (FGFR1) protein. Small molecule inhibition of BET proteins and FGFR1 simultaneously induces synergy in reducing GBM tumor growth in vitro and in vivo. Further, FGFR1 knockdown synergizes with BET inhibitor mediated reduction of GBM cell proliferation. Collectively, our studies suggest that co-targeting BET and FGFR1 may dampen resistance mechanisms to yield a clinical response in GBM.